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Methods of repairing tandemly repeated DNA sequences and extending cell life-span nuclear transfer

a nuclear transfer and dna sequence technology, applied in the field of repairing tandemly repeated dna sequences and extending cell lifespan nuclear transfer, can solve the problems of not showing evidence of cells, better results, and non-obvious longer telomeres, so as to increase cell life span or cell proliferation capacity, restore youthful gene expression patterns, and increase epc-1 activity

Inactive Publication Date: 2005-11-17
ADVANCED CELL TECH INC
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Benefits of technology

[0017] The present invention is based on the surprising discovery, in light of the recent doubts about the genetic age of cloned mammals, that the process of nuclear transfer is capable of rejuvenating senescent or near-senescent cells and repairing tandemly repeating DNA sequence such as that in the telomeres, restoring youthful patterns of gene expression such as increasing EPC-1 activity, and / or increases cell life span or cell proliferation capacity. The present invention therefore enables what would not have been deemed possible in light of the recent concerns about nuclear transfer; namely, that cells that are at or near senescence, e.g., those grown in culture until they are near senescence, or obtained from humans or animals having age-related defects or conditions may still be used to generate cloned cells, tissues and animals having telomeres that are at least comparable in length, or longer, than age-matched controls. Also, these cells possess patterns of gene expression of young cells, such as increased EPC-1 activity relation to donor cells. Moreover, the present invention establishes, in contrast to what had been recently suggested, that generating clones of clones, i.e. “re-cloning,” is entirely feasible, and may be repeated theoretically indefinitely, thereby resulting in “hyper-young” cells, tissues, organs and animals.
[0021] The present invention is based on the discovery that nuclear transfer techniques may be used to extend the life span of somatic cells, e.g., senescent or near-senescent or checkpoint arrested cells by activating endogenous (cellular) telomerase activity, and young patterns of gene expression by the repair of tandemly repeated DNA sequence damage. This provides particular advantages over recently suggested approaches for resolving the telomere loss seen in nuclear-transfer generated animals, which focus on the exogenous expression of a cloned telomerase gene to resolve telomere shortening in cloned mammals.
[0024] In addition, the present invention is advantageous over the exogenous expression of telomerase in that the culture of somatic cells leading to telomere shortening with subsequent nuclear transfer to extend telomeres results in a population of rejuvenated cells all of which have more uniform tracts of telomeric repeats. As a result individual cells isolated from such a population have a greater probability of being competent for extended proliferation and the population will have the unique property of having fewer checkpoint arrested cells than natural cells, thereby being “hyper young.”
[0026] The methods of the invention allow one to reprogram the nucleus of a late passage somatic cell to an embryonic state. By allowing the embryonic cell to differentiate and develop into many different cell types, one may re-isolate the primary cell of interest in a rejuvenated or “young” state. Also, since the methods of the invention entail making an embryonic stem cell which differentiates into all different cell types, any type of cell may be generated using any primary cell of interest, so long as the genome of the somatic cell has not been altered as to affect cellular development. Thus, the invention provides an invaluable way to analyze the affect of the same genetic alteration in an isogenic background (i.e., a gene knock-out or expression of a heterologous gene) in different cell types in vitro.
[0028] The methods of the present invention also increase the life-span of a desired cell, preferably a mammalian cell, and more preferably is a human cell, e.g., that is in need of rejuvenation, by using said cell, the nucleus or chromosomes therefrom, as a nuclear transfer donor. Preferably the process will be repeated, in that cells, nuclei or chromosomes obtained from the resultant cloned embryo will themselves be used as nuclear transfer donors. Also, the donor cells will preferably be transgenic.

Problems solved by technology

But the fact that starting from a senescent cell would lead to even better results (longer telomeres, longer lived cells) is nonobvious even in light of the former result.
However, to the inventors' knowledge, all of the published reports showed no evidence that cells could be obtained wherein the overall phenotype of such cells is younger or hyper-young.

Method used

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  • Methods of repairing tandemly repeated DNA sequences and extending cell life-span nuclear transfer
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  • Methods of repairing tandemly repeated DNA sequences and extending cell life-span nuclear transfer

Examples

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example 1

Fetal Donor Cells

[0091] This preliminary experiment suggested that somatic cell nuclear transfer can be used to restore the life-span of primary cultured cells. When fibroblasts from a six week-old fetus were cultured to senescence, they underwent approximately thirty population doublings, with an average cell cycle length of 28 to 30 hours. To test whether these cells could be rescued from senescence by nuclear transfer, a 40-day old fetus was generated using cells within 0.8 populations doublings from senescence. Fibroblasts derived from this fetus underwent 31 population doublings, as compared to 33 doublings for fibroblasts from a same-age fetus conceived normally. This data suggested that nuclear transfer is capable of rejuvenating senescent cells.

example 2

Cloned Calves Derived from Senescent Donor Somatic Cells

[0092] A somatic cell strain was derived from a 45-day-old female bovine fetus (BFF) and transfected with a PGK driven selection cassette. Cells were selected with G418 for 10 days, and five neomycin resistant colonies were isolated and analyzed for stable transfection by Southern blotting using a full length cDNA probe. One cell strain (CL53) was identified as 63% [total nuclei] positive for the transgene by FISH analysis, and was chosen for the nuclear transfer studies described in this study.

[0093] The CL53 fibroblast cells, which were characterized as negative for cytokeratin and positive for vimentin, were passaged until greater than 95% of their life-span was completed. The morphology of the cells was consistent with cells close to the end of their life-span as indicated by the phase contrast pictures of the cells by light microscopy (FIG. 1A). A more detailed ultrastructural analysis by electron microscopy demonstrated...

example 3

Nuclear Transfer Using Adult Donor Cells

[0104] The above data obtained with fetal fibroblast donors are consistent with experiments performed using senescent cells obtained from adult animals. Dermal fibroblasts were grown from three Holstein steers. Single cell clones were isolated and population doublings counted until senescence. Nuclear transfer was performed using these fibroblast cells that were at or near senescence. Fetuses were removed from the uterus at week 6 of gestation and fibroblasts isolated from them and cultured until senescence. Cells were analyzed by imunohistochemistry and were shown to be fibroblasts. The number of population doublings in the original cells from the adult animals at the time of nuclear transfer (counted as number of PDs before senescence) and from 6-week-old fetuses generated from them are shown in Table 1. Cell strains isolated from the cloned fetuses underwent an average of 89.4±0.9 PDs as compared to 60.5±1.7 PDs for cell strains generated ...

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Abstract

This invention relates to methods for rejuvenating normal somatic cells and for making normal somatic cells of a different type having the same genotype as a normal somatic cell of interest. These cells have particular application in cell and tissue transplantation. Also encompassed are methods of re-cloning cloned animals, particularly methods where the offspring of cloned mammals are designed to be genetically altered in comparison to their cloned parent, e.g., that are “hyper-young.” These animals should be healthier and possess desirable properties relative to their cloned parent. Also included are methods for activating endogenous telomerase, EPC-1 activity, and or the ALT pathway and / or extending the life-span of a normal somatic cell, and other genes associated with cell aging and proliferation capacity.

Description

CROSS-REFERENCE TO RELATED APPLICATION [0001] This application is a continuation-in-part of U.S. Ser. Nos. 09 / 527,026 and 09 / 520,879, and claims benefit of provisional application 60 / 152,340 and 60 / 153,233.FIELD OF INVENTION [0002] The present invention relates to methods for rejuvenating normal or modified somatic cells or cellular DNA that is senescent, checkpoint arrested, nearing senescence or has an undesirably short cell life, through nuclear transfer techniques. The methods are particularly useful for rejuvenating cells which have reached or are approaching senescence due to clonal expansion following complex genetic manipulations or from tissue chronic tissue injury, and thereby increase the potential of such cells to serve as donors for the generation of cloned transgenic animals or for cell therapy in humans. [0003] Also the invention is useful for rejuvenation of cells which are senescent or aged as a result of chronologic aging or because of conditions associated with ex...

Claims

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Application Information

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IPC IPC(8): C12N5/08C12N15/63C12N15/85C12Q1/68
CPCC12N2517/04C12N15/85
Inventor WEST, MICHAEL D.LANZA, ROBERT P.CIBELLI, JOSE
Owner ADVANCED CELL TECH INC
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